# Chapter I: establishing TCP connections In this chapter we will write together a `main.go` file that uses netxlite to establish a new TCP connection. (This file is auto-generated from the corresponding source file, so make sure you don't edit it manually.) ## The main.go file We define `main.go` file using `package main`. ```Go package main import ( "context" "errors" "flag" "net" "os" "time" "github.com/apex/log" "github.com/ooni/probe-cli/v3/internal/netxlite" ) ``` ### Main function ```Go func main() { ``` We use apex/log and configure it to emit debug messages. This setting will allow us to see netxlite emitted logs. ```Go log.SetLevel(log.DebugLevel) ``` We use the flags package to define command line options and we parse the command line options with `flag.Parse`. ```Go address := flag.String("address", "8.8.4.4:443", "Remote endpoint address") timeout := flag.Duration("timeout", 60*time.Second, "Timeout") flag.Parse() ``` We use the standard Go idiom to set a timeout using a context. ```Go ctx, cancel := context.WithTimeout(context.Background(), *timeout) defer cancel() ``` The bulk of the logic has been factored into a `dialTCP` function. ```Go conn, err := dialTCP(ctx, *address) ``` If there is a failure we invoke a function that prints the error that occurred and then calls `os.Exit(1)` ```Go if err != nil { fatal(err) } ``` Otherwise, we're tidy and close the opened connection. ```Go conn.Close() } ``` ### Dialing for TCP We construct a netxlite.Dialer (i.e., a type similar to net.Dialer) and we use it to dial the new connection. Note that the dialer we're constructing here is not attached to a resolver. This means that, if `address` contains a domain name rather than an IP address, the dial operation will fail. While it is possible in netxlite to construct a dialer using a resolver, here we're focusing on the step-by-step measuring perspective where we want to perform each operation independently. ```Go func dialTCP(ctx context.Context, address string) (net.Conn, error) { d := netxlite.NewDialerWithoutResolver(log.Log) return d.DialContext(ctx, "tcp", address) } ``` ### Printing the error Fundamental netxlite types guarantee that they always return a `*netxlite.ErrWrapper` type on error. This type is an `error` and we can use `errors.As` to see its content: - the Failure field is the OONI error string as specified in https://github.com/ooni/spec, and is also the string that is emitted in case one calls `err.Error`; - Operation is the name of the operation that failed; - WrappedErr is the underlying error that occurred and has been wrapped by netxlite. ```Go func fatal(err error) { var ew *netxlite.ErrWrapper if !errors.As(err, &ew) { log.Fatal("cannot get ErrWrapper") } log.Warnf("error string : %s", err.Error()) log.Warnf("OONI failure : %s", ew.Failure) log.Warnf("failed operation: %s", ew.Operation) log.Warnf("underlying error: %+v", ew.WrappedErr) os.Exit(1) } ``` ## Running the code ### Vanilla run You can now run this code as follows: ```bash go run -race ./internal/tutorial/netxlite/chapter01 ``` You will see debug logs describing what is happening along with timing info. ### Connection timeout ```bash go run -race ./internal/tutorial/netxlite/chapter01 -address 8.8.4.4:1 ``` should cause a connect timeout error. Try lowering the timout adding, e.g., the `-timeout 5s` flag to the command line. ### Connection refused ```bash go run -race ./internal/tutorial/netxlite/chapter01 -address '[::1]:1' ``` should give you a connection refused error in most cases. (We are quoting the `::1` IPv6 address using `[` and `]` here.) ## Conclusions We have seen how to use netxlite to establish a TCP connection.